Sex Reversal in Birds

Major, Andrew T.; Smith, Craig A.

doi:10.1159/000448365

Cited by 41 publications

(38 citation statements)

References 81 publications

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“…These findings are consistent with the finding that sexually dimorphic gene expression in chicken embryos can occur prior to the time of gonadal sex differentiation and hence predate any sexually dimorphic hormonal output (Ayers et al, 2013a, Lin et al, 2010, Major and Smith, 2016, O'Neill et al, 2000, Scholz et al, 2006, Zhang et al, 2010, Zhao et al, 2010. In a comparable experiment to that of Zhao et al, Maekawa et al, (2013) switched primordial brains between ZZ and ZW chicken embryos before gonadal sex differentiation (and vice versa) and raised birds to sexual maturity.…”

Section: Sex Determination and Sexual Developmentsupporting

confidence: 79%

Sex determination and gonadal sex differentiation in the chicken model

Hirst¹,

Major²,

Smith³

2018

Int. J. Dev. Biol.

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Our understanding of avian sex determination and gonadal development is derived primarily from the studies in the chicken. Analysis of gynandromorphic chickens and experimental chimeras indicate that sexual phenotype is at least partly cell autonomous in the chicken, with sexually dimorphic gene expression occurring in different tissue and different stages. Gonadal sex differentiation is just one of the many manifestations of sexual phenotype. As in other birds, the chicken has a ZZ male: ZW female sex chromosome system, in which the male is the homogametic sex. Most evidence favours a Z chromosome dosage mechanism underling chicken sex determination, with little evidence of a role for the W chromosome. Indeed, the W appears to harbour a small number of genes that are un-related to sexual development, but have been retained because they are dosage sensitive factors. As global Z dosage compensation is absent in birds, Z-linked genes may direct sexual development in different tissues (males having on average 1.5 to 2 times the expression level of females). In the embryonic gonads, the Z-linked DMRT1 gene plays a key role in testis development. Beyond the gonads, other combinations of Z-linked genes may govern sexual development, together with a role for sex steroid hormones. Gonadal DMRT1 is thought to activate other players in testis development, namely SOX9 and AMH, and the recently identified HEMGN gene. DMRT1 also represses ovarian pathway genes, such as FOXL2 and CYP19A1. A lower level of DMRT1 expression in the female gonads is compatible with activation of the ovarian pathway. Some outstanding questions include how the key testis and ovary genes, DMRT1 and FOXL2, are regulated. In addition, confirmation of the central role of these genes awaits genome editing approaches.

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Section: Sex Determination and Sexual Developmentsupporting

confidence: 79%

Sex determination and gonadal sex differentiation in the chicken model

Hirst¹,

Major²,

Smith³

2018

Int. J. Dev. Biol.

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“…Although sexual dimorphism can make male and female appear like two unrelated species, at genetic level, they differ only in genes on sex chromosome as in genetic sex determining species, or even in minuscule level if any as in environmental sex determining species. This similarity of genome between male and female may explain that sex change can happen naturally in several species [31,32]. These molecular and physiological evidence demonstrates that although sexual ambiguity is uncommon, it is a very natural manifestation of the genome and thus treating intersexes not as outliers but as an undeniable part of the population is very important.…”

Section: Discussionmentioning

confidence: 91%

Two Doublesex1 mutants revealed a tunable gene network underlying intersexuality in Daphnia magna

et al. 2020

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In recent years, the binary definition of sex is being challenged by repetitive reports about individuals with ambiguous sexual identity from various animal groups. This has created an urge to decode the molecular mechanism underlying sexual development. However, sexual ambiguities are extremely uncommon in nature, limiting their experimental value. Here, we report the establishment of a genetically modified clone of Daphnia magna from which intersex daphniids can be readily generated. By mutating the conserved central sex determining factor Doublesex1, body-wide feminization of male daphniid could be achieved. Comparative transcriptomic analysis also revealed a genetic network correlated with Doublesex1 activity which may account for the establishment of sexual identity in D. magna. We found that Dsx1 repressed genes related to growth and promoted genes related to signaling. We infer that different intersex phenotypes are the results of fluctuation in activity of these Dsx1 downstream factors. Our results demonstrated that the D. magna genome is capable of expressing sex in a continuous array, supporting the idea that sex is actually a spectrum.

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“…In mammals, sex determination results from two consecutive processes: (i) primary sex determination , which refers to the development of bi-potential gonads towards either male (testis) or female (ovary) pathways; and (ii) secondary sex determination , which refers to the development of the sexual dimorphic structures, directed by sex hormones produced in the differentiated gonads [ 13 , 14 ]. Sex reversal can be experimentally induced in chickens by oestrogen administration or production disturbance, indicating a role of this hormone in avian sex determination [ 15 ]. Vertebrate bi-potential gonads—along the evolutionary transition from lower to higher vertebrates—seem to display a gradual resistance to sex hormones.…”

Section: Introductionmentioning

confidence: 99%

“…Vertebrate bi-potential gonads—along the evolutionary transition from lower to higher vertebrates—seem to display a gradual resistance to sex hormones. Indeed, gonadal sex differentiation in fish [ 16 ] and amphibians [ 17 ] is generally susceptible to androgens and oestrogens; in reptiles [ 18 ], birds [ 15 ] and marsupials [ 19 ]; it is susceptible to oestrogens but not to androgens, whereas in eutherian mammals, gonadogenesis is resistant to hormone treatment [ 20 ].…”

Section: Introductionmentioning

confidence: 99%

Logical modelling uncovers developmental constraints for primary sex determination of chicken gonads

Sánchez

Chaouiya

2018

J. R. Soc. Interface.

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In the chicken, sex determination relies on a ZZ (male)/ZW (female) chromosomal system, but underlying mechanisms are still not fully understood. The Z-dosage and the dominant W-chromosome hypotheses have been proposed to underlie primary sex determination. We present a modelling approach, which assembles the current knowledge and permits exploration of the regulation of this process in chickens. Relying on published experimental data, we assembled a gene network, which led to a logical model that integrates both the Z-dosage and dominant W hypotheses. This model showed that the sexual fate of chicken gonads results from the resolution of the mutual inhibition between DMRT1 and FOXL2, where the initial amount of DMRT1 product determines the development of the gonads. In this respect, at the initiation step, a W-factor would function as a secondary device, by reducing the amount of DMRT1 in ZW gonads when the sexual fate of the gonad is settled, that is when the SOX9 functional level is established. Developmental constraints that are instrumental in this resolution were identified. These constraints establish qualitative restrictions regarding the relative transcription rates of the genes DMRT1, FOXL2 and HEMGN. Our model further clarified the role of OESTROGEN in maintaining FOXL2 function during ovary development.

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Sex Reversal in Birds

Cited by 41 publications

References 81 publications

Sex determination and gonadal sex differentiation in the chicken model

Sex determination and gonadal sex differentiation in the chicken model

Two Doublesex1 mutants revealed a tunable gene network underlying intersexuality in Daphnia magna

Logical modelling uncovers developmental constraints for primary sex determination of chicken gonads

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